Dynamics of Nitric Oxide Rebinding and Escape in ... - ACS Publications

Jan 25, 2006 - Received October 27, 2005; E-mail: [email protected]. Studies of the kinetics of diatomic ligand recombination to heme proteins follow...
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Dynamics of Nitric Oxide Rebinding and Escape in Horseradish Peroxidase Xiong Ye, Anchi Yu, and Paul M. Champion* Department of Physics and Center for Interdisciplinary Research on Complex System, Northeastern UniVersity, Boston, Massachusetts 02115 Received October 27, 2005; E-mail: [email protected]

Studies of the kinetics of diatomic ligand recombination to heme proteins following photodissociation can be used effectively to probe protein dynamics1 and help to reveal the diffusion pathway of the photodissociated ligand (NO, CO, and O2) within the dynamically fluctuating protein matrix. For example, cavities within the protein matrix of Mb, known as xenon pockets (i.e., Xe1-4), have been shown to play a crucial role in the diatomic ligand migration process.2 A variety of other kinetic studies involving ligand rebinding to myoglobin (Mb) and its mutants have been performed to help map out the ligand entrance and exit pathways of this prototypical heme system.1-4 In contrast to the diatomic ligand binding role of Mb, horseradish peroxidase (HRP) is a heme protein with peroxidase activity.5 Although it utilizes the same histidine-ligated heme prosthetic group as Mb to form the functional active site, HRP has a significantly altered distal pocket architecture and plays a very different physiological role than Mb. As a result, it would not be surprising if ligand diffusion inside the protein matrix was quite different. The rebinding of CO to HRP has been studied extensively,6,7 but only a single picosecond kinetics study has been reported,8 which found a relatively small CO geminate amplitude compared to the noise. On the other hand, we are aware of no prior study of the geminate recombination of nitric oxide to HRP. Since a large geminate amplitude (Ig) is observed for NO rebinding, a comparative study of NO rebinding in HRP and Mb reveals the effect of the distal pocket protein environment on the ligand rebinding and escape processes. In the case of NO rebinding to Mb, the kinetics are known to be nonexponential.9 Similar behavior is found in heme proteins, such as leghemoglobin10 and nitric oxide synthase.11 Recent temperature-dependent studies of the NO rebinding to Mb have revealed that the slower (∼200 ps) kinetic phase involves transitions of the NO ligand back into the distal pocket from a more distant site.12 The competitive inhibitor benzohydroxamic acid (BHA) is useful as a probe of the distal pocket substrate binding site of HRP. BHA binds with high affinity, and X-ray crystal structures of the BHA complexes of resting state (ferric) HRP and cyanide-ligated HRP have revealed that it binds on the distal side of the heme plane.13 BHA binding was observed to significantly change the CO rebinding kinetics,8,14 so that Ig increased from ∼20 to ∼90%, with a rate constant of 2 × 109 s-1. In addition, it was recently shown that binding of BHA significantly impedes oxygen access to the heme pocket.15 Here we report the first kinetic studies of the NO rebinding kinetics to HRP and investigate the effects of BHA on the rebinding kinetics. The transient spectra of the photolyzed ferric HRPNO display the photoproduct absorption near 390 nm,14 on the blue side of the ligated Soret peak, as is expected for a five-coordinated ferric heme species.4 Unlike native Mb, which shows multiple geminate phases, the NO geminate rebinding in HRP in both the ferric and ferrous states is well fit using a single exponential decay 1444

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J. AM. CHEM. SOC. 2006, 128, 1444-1445

Figure 1. (A) Kinetics of NO rebinding to ferric HRP (pumped at 403 nm and probed at 420 nm) and ferrous HRP (pumped at 403 nm and probed at 440 nm) using a dual synchronized picosecond-femtosecond laser system. (B) Kinetics of NO rebinding to ferrous native and mutant V68W Mb (pumped at 403 nm and probed at 440 nm). The data are fit by a single exponential decay convolved with a Gaussian response function (fwhm ) 3 ( 0.5 ps), except native Mb, which is fit with three exponential decays where the slower exponentials mimic the time-dependent barrier12 involved in the transition from the X- to B-state. The kinetics are normalized to unity at time zero.

(Figure 1). This demonstrates that nonexponential NO kinetics, as observed in Mb, do not arise from an inherent property of the heme relaxation.9a Additional measurements on ferric HRP also detect a small bimolecular rebinding phase with a 0.6 ms time constant.14 The kinetics can be described by a standard three-state scheme kout

HRPNO 79 HRP:NO {\ } HRP + NO k k BA

in

The kinetic fitting parameters,14 Ig ) kBA/kg and kg ) kout + kBA, along with the fundamental rates kBA and kout, are presented in Table 1. For ferric HRP, the addition of BHA significantly reduces kout and increases the geminate amplitude to near unity. These kinetic results suggest a very different process for internal ligand diffusion in HRP in comparison to Mb. The multiple exponential geminate rebinding in native MbNO reflects the dynamical process of ligand transitions between cavities.12,16 On the other hand, the single exponential geminate phase of HRPNO is similar to that of the V68W mutant of Mb,12 where the Xe4 cavity is blocked, indicating that there is no additional docking site or protein cavity in HRP that competes for the ligand following photolysis. The impact of BHA binding on the HRP kinetics further supports the existence of a single direct pathway for ligand escape from the distal heme cavity into the solvent. Blockage of this pathway by 10.1021/ja057172m CCC: $33.50 © 2006 American Chemical Society

COMMUNICATIONS Table 1. Kinetics of NO Rebinding to Horseradish Peroxidase (T ) 293 K) λpump (nm)

λprobe (nm)

kBA (1010 s-1)

ferric HRP ferric HRP+BHA ferric HRP ferric HRP+BHA

403 403 580 580

420 420 420 420

3.3 ( 0.1 6.0 ( 0.1 3.3 ( 0.4 4.0 ( 0.2

ferrous HRPa ferrous Mb (V68W)

403 403

440 440

15 ( 0.3 5.8 ( 0.2

ferrous Mb (WT)b

403

440

5.6 ( 0.2

NO bound sample

kout (1010 s-1)

kg (1010 s-1)

Ig (%)

1.0 ( 0.06 0.09 ( 0.02 0.9 ( 0.2 0.04 ( 0.04

4.3 ( 0.1 6.1 ( 0.1 4.2 ( 0.4 4.0 ( 0.1

76 ( 1 98.5 ( 0.3 78 ( 3 99 ( 1

0.8 ( 0.2